Enhanced steering wheel hold detection by a hybrid method

What is claimed is: 1. A method for determining whether a driver is holding onto a steering wheel of a steering system of a vehicle, the method comprising: providing steering torque data from a steering torque sensor on the vehicle; providing steering angle data from a steering angle sensor on the vehicle; performing, using a microprocessor, a passive hands-on/off detection process to determine a preliminary hands-on/off status, the passive hands-on/off detection process including: identifying a predominant resonant frequency in the steering angle data or the steering torque data; and comparing the predominant resonant frequency to a first specified hands-on frequency of the steering system and to a second specified hands-off frequency of the steering system; determining a confidence level in the preliminary hands-on/off status; setting a final hands-on/off status equal to the preliminary hands-on/off status responsive to the confidence level exceeding a confidence threshold; and performing, using the microprocessor responsive to the confidence level not exceeding the confidence threshold, an active hands-on/off detection process to determine a final hands-on/off status, the active hands-on/off detection process including: establishing a frequency, an amplitude, and a duration of a steering perturbation based on the preliminary hands-on/off status; applying the steering perturbation to the steering system of the vehicle by an electric power steering (EPS) motor; identifying the predominant resonant frequency in the steering angle data or the steering torque data for a time window of a predefined duration; and determining the final hands-on/off status based on whether the predominant resonant frequency remains within a predefined frequency range of the frequency of the steering perturbation for a predefined time period. 2. The method of claim 1 , wherein the passive hands-on/off detection process further includes: applying a band-pass filter at the first specified hands-on frequency to the steering angle data and the steering torque data; applying a band-pass filter at the second specified hands-off frequency to the steering angle data and the steering torque data; and selecting the steering angle data and the steering torque data for the time window. 3. The method of claim 2 , further comprising: comparing a steering torque value to a steering torque threshold; and responsive to the steering torque value being greater than or equal to the steering torque threshold, setting a steering override value equal to yes and determining that the vehicle driver is holding onto the steering wheel. 4. The method of claim 2 , wherein the first specified hands-on frequency is equal to a known steering system resonant frequency with the driver not holding onto the steering wheel, and the second specified hands-off frequency is equal to a known steering system resonant frequency with the driver holding onto the steering wheel. 5. The method of claim 2 , wherein determining the confidence level in the preliminary hands-on/off status includes setting the confidence level to exceed the confidence threshold responsive to the predominant resonant frequency remaining within a predefined frequency range of the first specified hands-on frequency or the second specified hands-off frequency for a predefined time period. 6. The method of claim 1 , wherein the active hands-on/off detection process further includes: modifying the frequency and the amplitude of the steering perturbation based on a vehicle speed and an engine speed; applying a band-pass filter, at a frequency substantially equal to the frequency of the steering perturbation, to the steering angle data and the steering torque data; selecting the steering angle data and the steering torque data for the time window; and setting the final hands-on/off status equal to the preliminary hands-on/off status responsive to the predominant resonant frequency remaining within the predefined frequency range of the frequency of the steering perturbation for the predefined time period. 7. The method of claim 6 , wherein the final hands-on/off status for a current iteration of the method is set equal to the final hands-on/off status for a previous iteration of the method responsive to the predominant resonant frequency not remaining within the predefined frequency range of the frequency of the steering perturbation for the predefined time period. 8. The method of claim 6 , further comprising: comparing a steering torque value to a steering torque threshold; and responsive to the steering torque value being greater than or equal to the steering torque threshold for a time exceeding a second time threshold, setting a steering override value equal to yes and determining that the vehicle driver is holding onto the steering wheel. 9. The method of claim 6 , wherein identifying the predominant resonant frequency in the steering angle data or the steering torque data for the time window includes using a Fast Fourier Transform (FFT) technique. 10. The method of claim 6 , wherein identifying the predominant resonant frequency in the steering angle data or the steering torque data for the time window includes counting a number of peaks above an amplitude threshold in the steering angle data or the steering torque data in the time window and using the number of peaks to determine the resonant frequency. 11. The method of claim 1 , wherein the final hands-on/off status is used by a Lane Centering Control (LCC) system or a Lane Keeping Assist (LKA) system on the vehicle. 12. A method for determining whether a driver is holding onto a steering wheel of a steering system of a vehicle, the method comprising: receiving, via a steering system controller of the vehicle, steering torque data from a steering torque sensor on the vehicle; receiving, via the steering system controller, steering angle data from a steering angle sensor on the vehicle; comparing a steering torque value to a steering torque threshold; responsive to the steering torque value being greater than or equal to the steering torque threshold for a time exceeding a time threshold, setting a steering override value equal to yes and determining that the vehicle driver is holding onto the steering wheel; performing, via the steering system controller, a passive hands-on/off detection process to determine a preliminary hands-on/off status, the passive hands-on/off detection process including: identifying a predominant resonant frequency of vibration in the steering angle data or the steering torque data; and comparing the predominant resonant frequency to a known hands-on resonant frequency of the steering system of the vehicle and to a known hands-off resonant frequency of the steering system; determining a confidence level in the preliminary hands-on/off status; setting a final hands-on/off status equal to the preliminary hands-on/off status if the confidence level exceeds a confidence threshold; and performing, via the steering system controller responsive to the confidence level not exceeding the confidence threshold, an active hands-on/off detection process to determine a final hands-on/off status, the active hands-on/off detection process including: establishing a frequency and an amplitude of a steering perturbation based on the preliminary hands-on/off status; applying the steering perturbation to the steering system by an electric power steering (EPS) motor; identifying the predominant resonant frequency in the steering angle data or the steering torque data for a time window of a predefined duration; and determining the final hands-on/off status based on whe